Soluble oligomers are sufficient for transmission of a yeast prion but do not confer phenotype

Abstract

Amyloidogenic proteins aggregate through a selftemplating mechanism that likely involves oligomeric or prefibrillar intermediates. For diseaseassociated amyloidogenic proteins, such intermediates have been suggested to be the primary cause of cellular toxicity. However, isolation and characterization of these oligomeric intermediates has proven difficult, sparking controversy over their biological relevance in disease pathology. Here, we describe an oligomeric species of a yeast prion protein in cells that is sufficient for prion transmission and infectivity. These oligomers differ from the classic prion aggregates in that they are soluble and less resistant to SDS. We found that large, SDS-resistant aggregates were required for the prion phenotype but that soluble, more SDS-sensitive oligomers contained all the information necessary to transmit the prion conformation. Thus, we identified distinct functional requirements of two types of prion species for this endogenous epigenetic element. Furthermore, the nontoxic, selfreplicating amyloid conformers of yeast prion proteins have again provided valuable insight into the mechanisms of amyloid formation and propagation in cells.

HPAN: A BioMed 21 IRC

The Hope Center Program on Protein Aggregation and Neurodegeneration (HPAN) is the most formalized of the Hope Center Research Groups. HPAN, led by Director David Holtzman, is one of five Interdisciplinary Research Centers (IRCs) based in the new BJC Institute of Health. This group focuses on the shared mechanism of protein aggregation that underlies numerous neurological disorders. Read more about HPAN....